Current and Emerging Basic Science Concepts in Bone Biology: Implications in Craniofacial Surgery

Overview

Journal J Craniofac Surg

Specialties Dentistry
General Surgery

Date 2012 Feb 17

PMID 22337370

Citations 13

Authors

Adam J Oppenheimer

John Mesa

Steven R Buchman

Affiliations

Soon will be listed here.

Abstract

Ongoing research in bone biology has brought cutting-edge technologies into everyday use in craniofacial surgery. Nonetheless, when osseous defects of the craniomaxillofacial skeleton are encountered, autogenous bone grafting remains the criterion standard for reconstruction. Accordingly, the core principles of bone graft physiology continue to be of paramount importance. Bone grafts, however, are not a panacea; donor site morbidity and operative risk are among the limitations of autologous bone graft harvest. Bone graft survival is impaired when irradiation, contamination, and impaired vascularity are encountered. Although the dura can induce calvarial ossification in children younger than 2 years, the repair of critical-size defects in the pediatric population may be hindered by inadequate bone graft donor volume. The novel and emerging field of bone tissue engineering holds great promise as a limitless source of autogenous bone. Three core constituents of bone tissue engineering have been established: scaffolds, signals, and cells. Blood supply is the sine qua non of these components, which are used both individually and concertedly in regenerative craniofacial surgery. The discerning craniofacial surgeon must determine the proper use for these bone graft alternatives, while understanding their concomitant risks. This article presents a review of contemporary and emerging concepts in bone biology and their implications in craniofacial surgery. Current practices, areas of controversy, and near-term future applications are emphasized.

Citing Articles

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Pediatric Cranial Vault Lesions: A Tailored Approach According to Bony Involvement.

Barbotti A, Vetrano I, Casali C, Galbiati T, Mariani S, Porto E Children (Basel). 2024; 11(11).

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Enhanced Osteogenesis Potential of MG-63 Cells through Sustained Delivery of VEGF via Liposomal Hydrogel.

Tsai M, Wahab R, Zainal Ariffin S, Azmi F, Yazid F Gels. 2023; 9(7).

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Engineering 3D Printed Bioceramic Scaffolds to Reconstruct Critical-Sized Calvaria Defects in a Skeletally Immature Pig Model.

DeMitchell-Rodriguez E, Shen C, Nayak V, Tovar N, Witek L, Torroni A Plast Reconstr Surg. 2023; 152(2):270e-280e.

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Bone regeneration in rat calvarial defects using dissociated or spheroid mesenchymal stromal cells in scaffold-hydrogel constructs.

Shanbhag S, Suliman S, Mohamed-Ahmed S, Kampleitner C, Hassan M, Heimel P Stem Cell Res Ther. 2021; 12(1):575.

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